Atmospheric Chemistry and Physics (Feb 2015)

Source sector and region contributions to BC and PM<sub>2.5</sub> in Central Asia

  • S. Kulkarni,
  • N. Sobhani,
  • J. P. Miller-Schulze,
  • M. M. Shafer,
  • J. J. Schauer,
  • P. A. Solomon,
  • P. E. Saide,
  • S. N. Spak,
  • Y. F. Cheng,
  • H. A. C. Denier van der Gon,
  • Z. Lu,
  • D. G. Streets,
  • G. Janssens-Maenhout,
  • C. Wiedinmyer,
  • J. Lantz,
  • M. Artamonova,
  • B. Chen,
  • S. Imashev,
  • L. Sverdlik,
  • J. T. Deminter,
  • B. Adhikary,
  • A. D'Allura,
  • C. Wei,
  • G. R. Carmichael

DOI
https://doi.org/10.5194/acp-15-1683-2015
Journal volume & issue
Vol. 15, no. 4
pp. 1683 – 1705

Abstract

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Particulate matter (PM) mass concentrations, seasonal cycles, source sector, and source region contributions in Central Asia (CA) are analyzed for the period April 2008–July 2009 using the Sulfur Transport and dEposition Model (STEM) chemical transport model and modeled meteorology from the Weather Research and Forecasting (WRF) model. Predicted aerosol optical depth (AOD) values (annual mean value ~0.2) in CA vary seasonally, with lowest values in the winter. Surface PM2.5 concentrations (annual mean value ~10 μg m−3) also exhibit a seasonal cycle, with peak values and largest variability in the spring/summer, and lowest values and variability in the winter (hourly values from 2 to 90 μg m−3). Surface concentrations of black carbon (BC) (mean value ~0.1 μg m−3) show peak values in the winter. The simulated values are compared to surface measurements of AOD as well as PM2.5, PM10, BC, and organic carbon (OC) mass concentrations at two regional sites in Kyrgyzstan (Lidar Station Teplokluchenka (LST) and Bishkek). The predicted values of AOD and PM mass concentrations and their seasonal cycles are fairly well captured. The carbonaceous aerosols are underpredicted in winter, and analysis suggests that the winter heating emissions are underestimated in the current inventory. Dust, from sources within and outside CA, is a significant component of the PM mass and drives the seasonal cycles of PM and AOD. On an annual basis, the power and industrial sectors are found to be the most important contributors to the anthropogenic portion of PM2.5. Residential combustion and transportation are shown to be the most important sectors for BC. Biomass burning within and outside the region also contributes to elevated PM and BC concentrations. The analysis of the transport pathways and the variations in particulate matter mass and composition in CA demonstrates that this region is strategically located to characterize regional and intercontinental transport of pollutants. Aerosols at these sites are shown to reflect dust, biomass burning, and anthropogenic sources from Europe; South, East, and Central Asia; and Russia depending on the time period. Simulations for a reference 2030 emission scenario based on pollution abatement measures already committed to in current legislation show that PM2.5 and BC concentrations in the region increase, with BC growing more than PM2.5 on a relative basis. This suggests that both the health impacts and the climate warming associated with these particles may increase over the next decades unless additional control measures are taken. The importance of observations in CA to help characterize the changes that are rapidly taking place in the region are discussed.